The Longest Common Substring (LCS) problem is as follows:
Given two strings s and t, find the length of the longest string r, which is a substring of both s and t.
This problem is a classic application of Dynamic Programming. Let's define the sub-problem (state) P[i][j] to be the length of the longest substring ends at i of s and j of t. Then the state equations are
This algorithm gives the length of the longest common substring. If we want the substring itself, we simply find the largest P[i][j] and return s.substr(i - P[i][j] + 1, P[i][j]) or t.substr(j - P[i][j] + 1, P[i][j]).
Then we have the following code.
1 string longestCommonSubstring(string s, string t) { 2 int m = s.length(), n = t.length(); 3 vector<vector<int> > dp(m, vector<int> (n, 0)); 4 int start = 0, len = 0; 5 for (int i = 0; i < m; i++) { 6 for (int j = 0; j < n; j++) { 7 if (i == 0 || j == 0) dp[i][j] = (s[i] == t[j]); 8 else dp[i][j] = (s[i] == t[j] ? dp[i - 1][j - 1] + 1: 0); 9 if (dp[i][j] > len) { 10 len = dp[i][j]; 11 start = i - len + 1; 12 } 13 } 14 } 15 return s.substr(start, len); 16 }
The above code costs O(m*n) time complexity and O(m*n) space complexity. In fact, it can be optimized to O(min(m, n)) space complexity. The observations is that each time we update dp[i][j], we only need dp[i - 1][j - 1], which is simply the value of the above grid before updates.
Now we will have the following code.
1 string longestCommonSubstringSpaceEfficient(string s, string t) { 2 int m = s.length(), n = t.length(); 3 vector<int> cur(m, 0); 4 int start = 0, len = 0, pre = 0; 5 for (int j = 0; j < n; j++) { 6 for (int i = 0; i < m; i++) { 7 int temp = cur[i]; 8 cur[i] = (s[i] == t[j] ? pre + 1 : 0); 9 if (cur[i] > len) { 10 len = cur[i]; 11 start = i - len + 1; 12 } 13 pre = temp; 14 } 15 } 16 return s.substr(start, len); 17 }
In fact, the code above is of O(m) space complexity. You may choose the small size for cur and repeat the same code using if..else.. to save more spaces :)